Injection Device Having Variable Dosing

ABSTRACT

An injection device for injecting medicament in a patient comprises a housing configured to house a fluid reservoir that has one of a plurality of volumes of medicament. An injection conduit fluidly coupled to the fluid reservoir defines a fluid pathway from the fluid reservoir to the patient. A firing mechanism is coupled to the fluid reservoir and is configured to expel the medicament from the fluid reservoir through the injection conduit. A volume setting mechanism is coupled to the firing mechanism and is configured to select the one of the plurality of volumes of medicament for the firing mechanism to expel. A dose setting mechanism is configured to select all or a fraction of the one of the plurality of volumes of medicament that is injected from the injection conduit when the firing mechanism is actuated.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.15/545,358 filed Jul. 21, 2017, which is a U.S. National Stage ofInternational Patent Application No. PCT/US2016/014217, filed Jan. 21,2016, which claims the benefit of U.S. Provisional Patent ApplicationNo. 62/105,897 filed Jan. 21, 2015, U.S. Provisional Patent ApplicationNo. 62/116,836 filed Feb. 16, 2015, and U.S. Provisional PatentApplication No. 62/140,023 filed Mar. 30, 2015, which are all entitled“Injection Device Having Variable Dosing” and each is incorporated byreference herein in its entirety.

FIELD OF THE INVENTION

The present invention generally relates to an injection device havingvariable dosing, and in some embodiments, to an auto-injection devicehaving variable dosing.

BACKGROUND OF THE INVENTION

Injection devices for injection of medicaments into a patient aregenerally known. Such devices include, for example, traditionalhypodermic needle syringes that contain a stock of medicament therein.Upon insertion of the needle under the patient's skin at an injectionlocation, the medicament is forced out of the syringe and through theneedle by depression of a plunger mechanism.

Self-injectors or auto-injectors like the ones disclosed in U.S. Pat.Nos. 4,553,962 and 4,378,015, and PCT Patent Application Publications WO95/29720 and WO 97/14455 are configured to inject medicament at a rateand in a manner similar to hand-operated hypodermic syringes.

These injectors often are made for a single use, or alternatively to berefilled after each injection. Some refillable injectors can be refilledwith a desired dosage to be injected. Upon injection, the entire loadeddosage is injected.

BRIEF SUMMARY OF THE INVENTION

In one embodiment there is an injection device for injecting medicamentin a patient comprising: a housing configured to house a fluid reservoirhaving one of a plurality of volumes of medicament; an injection conduitfluidly coupled to the fluid reservoir configured to define a fluidpathway from the fluid reservoir to the patient; a firing mechanismcoupled to the fluid reservoir and configured to expel the medicamentfrom the fluid reservoir through the injection conduit; a volume settingmechanism coupled to the firing mechanism and configured to be adjustedto select the one of the plurality of volumes of medicament for thefiring mechanism to expel; and a dose setting mechanism configured to beadjusted to select a fraction of the one of the plurality of volumes ofmedicament that is injected from the injection conduit when the firingmechanism is actuated.

In one embodiment, the volume setting mechanism includes a nut and thefiring mechanism includes a ram and a biasing member, the nut beingthreadably coupled to the ram, the nut being releaseably retainedagainst a force of the biasing member in an initial position by a latch.In one embodiment, the nut includes a plurality of indentations eachconfigured to engage with a projection of the latch. In one embodiment,each of the plurality of indentations includes a ring shaped grooveextending circumferentially around the nut. In a further embodiment, theinjection device comprises a guard that is slideably coupled to thehousing, wherein the guard is configured to release the latch from thenut. In a further embodiment, the injection device comprises a biasingmember coupled to the guard and configured to bias the guard toward adistal end of the injection device, the guard configured to extendaxially past the injection conduit.

In one embodiment, the guard extends further distally in a lockedposition than in an initial position. In one embodiment, the nut isrotatable relative to the latch. In one embodiment, the nut isconfigured to couple to the latch in one of a plurality of positionsalong an axial length of the nut, each of the plurality of positionsalong the axial length of the nut corresponding to one of the pluralityof volumes of medicament for the firing mechanism to expel. In oneembodiment, the volume setting mechanism includes a ram extensionthreadably coupled to the ram, the ram extension configured to extendthe length of the ram to one of a plurality of positions correspondingto one of the plurality of volumes of medicament for the firingmechanism to expel. In one embodiment, the ram is rotatably fixed andaxially moveable relative to the dose setting mechanism.

In one embodiment, the latch includes a latch arm releaseably retainingthe nut in the initial position and a stop engaging the nut in a firedposition, a distance between the latch arm and the stop being fixed. Inone embodiment, the volume setting mechanism includes a retainer and alatch and the firing mechanism includes a ram and a biasing member, thelatch being coupled between the biasing member and the ram, the latchbeing retained against a force of the biasing member in an initialposition by the retainer. In a further embodiment, the injection devicecomprises a stop having a plurality of axially extending and radiallyprojecting slots each extending a different axial depth, wherein the ramincludes a wing extending radially from the ram and configured to engageone of the plurality of slots in a fired position.

In one embodiment, the stop and the retainer are integrally connected.In one embodiment, the dose setting mechanism is rotatably coupled tothe ram to radially align the wing with one of the plurality of slots inthe initial position. In one embodiment, the ram includes a prime screwthreadably coupled to the end of the ram, the prime screw configured tocouple the ram to a piston. In one embodiment, the ram remains incontact with the piston independent of the position of the dose settingmechanism. In one embodiment, the latch includes a plurality of axiallyspaced indentations each configured to engage with a projection of theretainer. In a further embodiment, the injection device comprises aguard that is slideably coupled to the housing, wherein the guardincludes a sidewall configured to prevent radial motion of the retainerin the initial position and an aperture in the sidewall configured toallow radial motion of the retainer in a retracted position.

In one embodiment, the ram is rotatably fixed and axially moveablerelative to the dose setting mechanism. In one embodiment, the dosesetting mechanism includes a shaft extending partially into and radiallykeyed with an inner shaft of the ram in the initial position and a firedposition. In one embodiment, the latch is axially fixed and rotatablymoveable relative to the ram. In one embodiment, the firing mechanismincludes a spring and the position of the spring being independent fromthe position of the dose setting mechanism. In one embodiment, the dosesetting mechanism includes a knob rotatably coupled to the housing. In afurther embodiment, the injection device comprises a guard slideablycoupled to the housing and configured to extend axially past theinjection conduit and lock relative to the housing after removing theinjection conduit from the patient.

In one embodiment, the injection conduit comprises a needle. In afurther embodiment, the injection device comprises a syringe containingthe fluid reservoir, wherein the needle is fixed to the syringe. In oneembodiment, the injection device is configured to prevent resettingafter the firing mechanism is actuated so as to prevent a subsequentinjection of the medicament by the injection device, thereby configuringthe injection device as a single-use injector. In a further embodiment,the injection device comprises a safety cap coupled to a distal end ofthe housing, the safety cap being coupled to the firing mechanism suchthat decoupling the safety cap from the housing allows the firingmechanism to advance a predetermined distance relative to the fluidreservoir to prime the fluid reservoir. In one embodiment, actuating thedose setting mechanism advances the firing mechanism a predetermineddistance relative to the fluid reservoir to prime the fluid reservoir.In one embodiment, the firing mechanism is configured to deliver each ofthe selected fraction of the one of the plurality of volumes ofmedicament over a generally equal amount of time as compared to oneanother. In one embodiment, the fraction is only greater than or equalto 0.5. In one embodiment, the selected fraction results in a residualvolume remaining in the fluid reservoir after delivery of 0.18 ml orless.

In another embodiment, there is an injection device for injectingmedicament in a patient comprising: a firing mechanism having anactuator and configured to be selectively preset during assembly to oneof a plurality of positions based on a maximum volume of medicament tobe delivered to the patient; and a dose setting mechanism configured tobe selectably adjusted upon use, independent of the preset of the firingmechanism, to select a fraction of the maximum volume of medicament tobe delivered to the patient.

In another embodiment there is an injection device for injectingmedicament in a patient comprising: a housing configured to house afluid container having a piston and a fluid reservoir having one of aplurality of volumes of medicament, the fluid container including aninjection conduit fluidly coupled to the fluid reservoir defining afluid pathway from the fluid reservoir to the patient; a ram coupled tothe piston and configured to expel the medicament from the fluidreservoir through the injection conduit; a spring biasing the ram towardthe fluid container in an initial position; a nut threadably coupled tothe ram, the nut having a plurality of ring shaped grooves orprojections; a latch fixed relative to the housing and engaging apredetermined one of the plurality of ring shaped grooves or projectionsto retain the ram in one of a plurality of axial positions against aforce of the spring in the initial position, the nut being rotatablerelative to the latch in the initial position; and a dose setting knobrotatably coupled to the housing and rotatably fixed and axiallymoveable relative to the ram in the initial position.

In another embodiment there is an injection device for injectingmedicament in a patient comprising: a housing configured to house afluid container having a piston and a fluid reservoir having one of aplurality of volumes of medicament, the fluid container including aninjection conduit fluidly coupled to the fluid reservoir defining afluid pathway from the fluid reservoir to the patient; a ram coupled tothe piston and configured to expel the medicament from the fluidreservoir through the injection conduit, the ram having a radiallyextending wing; a latch axially fixed and rotatably moveable relative tothe ram, the ram having a plurality of radial features; a spring biasingthe latch toward the fluid container in an initial position; a retainerfixed relative to the housing and engaging a predetermined one of theplurality of radial features to retain the ram in one of a plurality ofaxial positions against a force of the spring in the initial position; astop having a plurality of axially extending and radially projectingslots each extending a different axial depth, the ram being rotatable toalign the wing with one of the plurality of slots in the initialposition and the wing configured to engage the one of the plurality ofslots in a fired position; and a dose setting knob rotatably coupled tothe housing, the ram being rotatably fixed and axially moveable relativeto the dose setting knob.

In another embodiment there is a method for assembling an injectiondevice comprising: inserting a fluid container having a fluid reservoirincluding one of a plurality of volumes of medicament into a housing,the fluid container including an injection conduit fluidly coupled tothe fluid reservoir defining a fluid pathway from the fluid reservoir tothe patient; setting a volume setting mechanism based on a size of theone of the plurality of volumes of the medicament; coupling the volumesetting mechanism to a firing mechanism; and coupling the firingmechanism to the fluid reservoir, the firing mechanism configured toexpel the medicament from the fluid reservoir through the injectionconduit, the firing mechanism being coupled to a dose setting mechanismconfigured to select all or a fraction of the one of the plurality ofvolumes of medicament that is injected from the injection conduit whenthe firing mechanism is actuated.

In another embodiment there is an injection device for injectingmedicament in a patient comprising: a housing configured to house afluid reservoir; an injection conduit fluidly coupled to the fluidreservoir defining a fluid pathway from the fluid reservoir to thepatient; a firing mechanism coupled to the fluid reservoir andconfigured to expel the medicament from the fluid reservoir through theinjection conduit; and a safety cap coupled to a distal end of thehousing, the safety cap being coupled to the firing mechanism such thatdecoupling the safety cap from the housing allows the firing mechanismto advance a predetermined distance relative to the fluid reservoir toprime the fluid reservoir.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

The following detailed description of embodiments of the injectiondevice having variable dosing will be better understood when read inconjunction with the appended drawings of exemplary embodiments. Itshould be understood, however, that the invention is not limited to theprecise arrangements and instrumentalities shown.

In the Drawings:

FIG. 1 is a side view of an injection device in accordance with anexemplary embodiment of the present invention;

FIG. 2 is an exploded perspective view of the injection device of FIG. 1;

FIG. 3A is a first side view of the injection device of FIG. 1 ;

FIG. 3B is a cross sectional side view of the injection device shown inFIG. 3A taken along a plane indicated by line A-A;

FIG. 3C is a second side view of the injection device of FIG. 1 turned90 degrees from the view shown in FIG. 3A;

FIG. 3D is a cross sectional side view of the injection device shown inFIG. 3C taken along a plane indicated by line B-B;

FIG. 3E is a cross sectional top view of the injection device shown inFIG. 3C taken along a plane indicated by line 3E-3E;

FIG. 4A is a second side view of the injection device of FIG. 1 ;

FIG. 4B is a cross sectional side view of the injection device shown inFIG. 4A taken along a plane indicated by line B-B;

FIG. 4C is an enlarged cross sectional side view of a portion of theinjection device shown in FIG. 4B within the circled area;

FIG. 4D is an enlarged cross sectional side view of a portion of theinjection device shown in FIG. 4C within the circled area;

FIG. 5A is a first side view of the injection device of FIG. 1 shownwith the housing removed and in the un-primed position;

FIG. 5B is a second side view of the injection device of FIG. 1 shownwith the housing removed, turned 90 degrees from the first side viewshown in FIG. 5A and shown in the un-primed position;

FIG. 5C is a cross sectional side view of the injection device shown inFIG. 5B taken along a plane indicated by line B-B;

FIG. 5D is a second side view of the injection device of FIG. 1 shown inthe primed position;

FIG. 5E is a cross sectional side view of the injection device shown inFIG. 5D taken along a plane indicated by line C-C;

FIG. 5F is a top view of the injection device shown in FIG. 5D;

FIG. 6A is a side view of the injection device of FIG. 1 shown in theinitial position;

FIG. 6B is a cross sectional side view of the injection device shown inFIG. 6A taken along a plane indicated by line I-I;

FIG. 7A is a side view of the injection device of FIG. 1 shown in theminimum dose position;

FIG. 7B is a cross sectional side view of the injection device shown inFIG. 7A taken along a plane indicated by line A-A;

FIG. 8A is a side view of the injection device of FIG. 1 shown in theinsertion position;

FIG. 8B is a cross sectional side view of the injection device shown inFIG. 8A taken along a plane indicated by line J-J;

FIG. 9A is a side view of the injection device of FIG. 1 shown in thereleased position;

FIG. 9B is a cross sectional side view of the injection device shown inFIG. 9A taken along a plane indicated by line K-K;

FIG. 10A is a side view of the injection device of FIG. 1 shown in thefired position;

FIG. 10B is a cross sectional side view of the injection device shown inFIG. 10A taken along a plane indicated by line L-L;

FIG. 11A is a side view of the injection device of FIG. 1 turned 90degrees from the side view of FIG. 10A;

FIG. 11B is a cross sectional side view of the injection device shown inFIG. 11A taken along a plane indicated by line M-M;

FIG. 12A is a side view of the injection device of FIG. 1 shown in thelocked out position;

FIG. 12B is a cross sectional side view of the injection device shown inFIG. 12A taken along a plane indicated by line N-N;

FIGS. 13A-13C are views of the injection device of FIG. 1 shown in theinitial position with the housing removed;

FIGS. 14A-14C are views of the injection device of FIG. 1 shown in theinsertion position with the housing removed;

FIGS. 15A-15C are views of the injection device of FIG. 1 shown in thereleased position with the housing removed;

FIGS. 16A-16C are views of the injection device of FIG. 1 in the firedposition with the housing removed;

FIG. 17 is an illustration of the mechanical advantage of the latch ofthe injection device of FIG. 1 ;

FIGS. 18A-18D are various views of a ram of the injection device of FIG.1 ;

FIGS. 19A and 19B are side views of an injection device in accordancewith an exemplary embodiment of the present invention;

FIGS. 19C and 19D are side cross sectional views of the injection deviceof FIGS. 19A and 19B respectively;

FIG. 20A is a first exploded perspective view of the injection device ofFIG. 19A;

FIG. 20B is a second exploded perspective view of the injection deviceof FIG. 19A;

FIGS. 21A-21C are various side views of the latch, ram and slot stop ofthe injection device of FIG. 19A;

FIGS. 22A-22F are various views of the slot stop of the injection deviceof FIG. 19A;

FIGS. 23A-231 include various views of the ram and the ram and dose knobassembly of the injection device of FIG. 19A;

FIGS. 24A-24E are various side and perspective views of the injectiondevice of FIG. 19A with the housing and other components removed in theinitial, untriggered position;

FIGS. 25A-25E are various side and perspective views of the injectiondevice of FIG. 19A with the housing and other components removed in theinsertion or retraction position;

FIGS. 26A-26D are various side and perspective views of the injectiondevice of FIG. 19A with the housing and other components removed in thetriggered position;

FIGS. 27A-27D are various side and perspective views of the injectiondevice of FIG. 19A with the housing and other components removed in thelocked out position;

FIGS. 28A-28C are various views of the ram and slot stop of theinjection device of FIG. 19A shown in the minimum dose setting beforethe dose is delivered;

FIG. 29 is a perspective view of the ram and slot stop of FIGS. 28-28Cshown after the dose is delivered;

FIGS. 30A-30C are various views of the ram and slot stop of theinjection device of FIG. 19A shown in the maximum dose setting beforethe dose is delivered;

FIGS. 31A-31B are side and side cross-sectional views respectively ofthe ram and slot stop of FIGS. 30A-30C shown after the dose isdelivered;

FIG. 32 is a perspective view of a safety cap having a spacer for usewith the injection device of FIG. 19A;

FIGS. 33A-33D are cross sectional side views of the injection device ofFIG. 19A having the safety cap shown in FIG. 32 ;

FIGS. 34A and 34B are cross sectional side views of on the injectiondevice of FIG. 19A having a priming release pin;

FIGS. 35 a and 35 b are cross sectional sketches of the latch, slot stopand guard of the injection device of FIG. 19A illustrating a primingconfiguration;

FIG. 36 is a side cross sectional sketch of the injection device of FIG.19A having an expandable ram for priming;

FIG. 37 is a perspective view of a latch for an injection device inaccordance with an exemplary embodiment of the present invention;

FIGS. 38A and 38B are side views of a lock-out system for an injectiondevice in accordance with an exemplary embodiment of the presentinvention with the outer housing removed and shown in an initialposition;

FIGS. 39A, 39B and 39C are various views of a guard of the injectiondevice of FIGS. 38A and 38B;

FIG. 40 is an enlarged side view of the front retainer retaining theguard shown within circle A of FIG. 38A;

FIGS. 41A and 41B are side views of a sleeve of the injection device ofFIGS. 38A and 38B;

FIG. 42 is a side view of the front retainer and guard of FIG. 40 shownin a release position after the dose has been delivered; and

FIGS. 43A and 43B are side views of the guard, sleeve and front retainerand the guard and the sleeve respectively of the injection device ofFIGS. 38A and 38B rotated 90 degrees from the view shown in FIG. 42 andwith the guard extended and in the locked out position.

DETAILED DESCRIPTION OF THE INVENTION

Referring to the drawings in detail, wherein like reference numeralsindicate like elements throughout, there is shown in FIGS. 1-18D aninjection device, generally designated 110, a first exemplary embodimentof the present invention. Various embodiments of the injection device110 are described in further detail below in reference to the exemplaryembodiment shown in the figures.

The injection device 110 is configured to deliver a selected amount ofone of a plurality of predetermined volumes of medicament to a patient.The injection device 110 is assembled using one of a plurality of fluidreservoirs and the dose that is ultimately delivered to the patient isequal to or less than the full amount contained in the injection device110. This allows for the injection device 110 to accept fluidcartridges, prefilled syringes or similar containers being filled todifferent volumes and/or multiples sizes of fluid containers and thenallows for the user to select how much of the fluid in the fluidcontainer to deliver. Such flexibility allows for one device to beadapted for multiple medicament volumes and ultimately reduces theamount of wasted medicament.

For example, a typical injection device may have a volume of 1.0 ml toencompass the range of potential dosages needed. A patient who isprovided a 1.0 ml device but only needs a dosage of 0.5 ml, would leavea residual volume of 0.5 ml in the discarded device. Instead, thepatient, requiring a dosage of 0.5 ml, can be provided a 1.0 mlinjection device 110 containing 0.6 ml of fluid, resulting in a residualvolume of only 0.1 ml in the discarded device. By allowing adjustment ofthe volume, the manufacturer can easily set the injection device 110 toone of a plurality of volumes to divide up the range of dosagesselectable by a patient and reduce the amount of residual fluid left inthe discarded device.

The injection device 110 includes an actuator for driving fluid from theinjection device 110 into the patient. In some embodiments, the actuatoris automatically actuated as a result of positioning the injectiondevice 110 relative to the skin surface, also referred to as anauto-injection device. The injection device 110 may include a needle. Inother embodiments, the injection device does not include a needle andthe injection port of the fluid chamber preferably defines a fluidpathway in fluid communication with the fluid chamber for injectingmedicament as a jet from the chamber through the port to the injectionlocation. An example of a suitable needle-free jet nozzle arrangement isdisclosed in U.S. Pat. No. 6,309,371, which is incorporated by referencein its entirety.

As disclosed in further detail below, in some embodiments, the injectiondevice 110 includes a firing mechanism having an actuator, a volumesetting mechanism configured to be selectively preset during assembly toone of a plurality of positions based on a maximum volume of medicamentto be delivered to the patient (e.g., one of a 0.4 ml, 0.6 ml, 0.8 ml or1.0 ml prefilled syringe) and a dose setting mechanism configured to beselectably adjusted upon use, independent of the preset of the volumesetting mechanism, to select a fraction of the maximum volume ofmedicament to be delivered to the patient (e.g., a 0.2 ml to 0.4 ml dosefor a 0.4 ml syringe).

Referring to FIG. 1 , the injection device 110 may include a housing112. The housing 112 extends along a longitudinal axis A and isconfigured to be held in one hand of a patient or caregiver to deliverthe dose of medicament to the patient. In one embodiment, the housing112 is cylindrical. In other embodiments, the cross sectional shape ofthe housing 112 is elliptical, triangular, square or any other desiredshape. The housing 112 may include one or more windows 112 a, 112 b forviewing components of the injection device 110 contained within thehousing 112. The windows 112 a, 112 b may be covered with a transparentmaterial. Windows 112 a, 112 b may allow the viewing of the fluidreservoir 118 within the housing 112. The window 112 a, 112 b may alsoallow viewing of the preset volume that has been chosen. In anotherembodiment, the window 112 a, 112 b allows viewing that the injectiondevice 110 is ready for use. In another embodiment, the window 112 a,112 b allows viewing that the injection is complete. Other uses of awindow to allow viewing internal aspects of the injection device areanticipated. In an embodiment, the window 112 a, 112 b allows viewing ofinjection device internal components that assist in administering aninjection. In one embodiment, the housing 112 is comprised partially orentirely of a transparent material.

Referring to FIG. 3B, the housing 112 is configured to house a fluidreservoir 118 having one of a plurality of volumes of medicament. Thedesired volume of the fluid reservoir 118 is selected before assemblingthe injection device 110. In one embodiment, the desired volume of thefluid reservoir 118 is based on the desired maximum dose that thepatient will be able to inject. In one embodiment, the injection device110 is configured to receive one sized container or syringe having afluid reservoir 118 configured to accommodate a plurality (e.g., four)different maximum volumes for injection. In other embodiments, theinjection device 110 is configured to receive a fluid reservoirconfigured to accommodate two, three, or five or more different maximumvolumes for injection. In other embodiments, the injection device 110 isconfigured to receive one of four differently sized containers having afluid reservoir 118. In other embodiments, the injection device 110 isconfigured to receive one of two, three, five or more differently sizedcontainers having fluid reservoirs 118. In one embodiment, the fluidreservoir 118 contains one of 0.4 ml, 0.6 ml, 0.8 ml, or 1.0 ml ofmedicament. In other embodiments, the fluid reservoir 118 contains otheramounts of medicament such as one or more of the following amounts: 0.04ml, 0.05 ml, 0.06 ml, 0.07 ml, 0.08 ml, 0.09 ml, 0.1 ml, 0.2 ml, 0.3 ml,0.4 ml, 0.5 ml, 0.6 ml, 0.7 ml, 0.8 ml 0.9 ml, 1.0 ml, 1.1 ml, 1.2 ml,1.3 ml, 1.4 ml, 1.5 ml, 1.6 ml, 1.7 ml, 1.8 ml, 1.9 ml, 2.0 ml, greaterthan 2.0 ml, less than 0.010 ml and any amount between these numbers. Inone embodiment, the fluid reservoir 118 includes a prefilled syringehaving a piston 120 forming a sliding seal at a proximal end. Aninjection conduit 122 is fluidly coupled to the fluid reservoir defininga fluid pathway from the fluid reservoir to the patient. In oneembodiment, the injection conduit 122 is a needle. The needle 122 may bestaked to the prefilled syringe.

Referring to FIG. 3B, the needle 122 may be covered by a needle cap 124in the stowed or initial position. The needle cap 124 may include anelastomeric material for sealing and protecting the needle 122 in theinitial position. Referring to FIG. 1 , the injection device 110 mayfurther or alternatively include a safety cap 114 that is releaseablycoupled to a distal end 110 a of the injection device 110. The safetycap 114 covers the injection conduit 118 in the initial position toprevent contamination and accidental needle sticks or actuation of theactuator. The safety cap 114 may be coupled to the needle cap 124 suchthat removing the safety cap 114 from the housing 112 also strips theneedle cap 124 from the needle 122 and exposes the needle 122.

The injection device 110 may include a firing mechanism coupled to thefluid reservoir 118 and configured to expel the medicament from thefluid reservoir 118 through the injection conduit 122 (see FIG. 3B). Thefiring mechanism may include an actuator such as a biasing member 126.In one embodiment, the biasing member 126 includes a compression spring.In another embodiment, the actuator is pneumatically driven. The biasingmember 126 may be operatively associated with a ram 128 extending alongthe longitudinal axis A. The ram 128 may include a keyed proximal end128 a and one or more male or female threads 128 b. The ram 128 mayinclude a pair of diametrically opposed threadless portions 128 eextending along the length of the ram 128 (see FIGS. 18A-18D). In oneembodiment the threadless portion 128 e may serve as a keyed feature totransfer torque or provide location to an adjacent component. Thethreadless portions 128 e may be recessed relative to the threads 128 bto allow for a flash or other manufacturing artifact to exist on thethreadless portion 128 e without interfering with the use of the threads128 b. The ram 128 may be coupled to the fluid reservoir 118 such thatthe biasing member 126 urges the ram 128 to compress the fluid reservoir118 and deliver the medicament to the patient through the injectionconduit 122. In one embodiment, the ram 128 is coupled to the piston120. The ram 128 may include a projection 128 c extending distally forsupporting the engagement between the ram 128 and the piston 120 (seeFIG. 3B).

Referring to FIGS. 4A-4D, the volume setting mechanism may be set toprovide the one of the plurality of volumes of medicament. The volumesetting mechanism may include a nut 130 that is releaseably retained inthe axial direction against a force of the biasing member 126 in aninitial position by a latch 132 (see FIG. 3B). The latch 132 may includea projection 132 a that engages a corresponding indent 130 a in the nut130 to prevent axial movement of the nut 130 in the initial position.

The nut 130 may include a plurality of indentations 130 a eachconfigured to engage with the projection 132 a of the latch. Each of theplurality of indentations may be axially spaced from one another. Eachof the plurality of indentations 130 a of the nut 130 may include a ringshaped groove extending circumferentially around the nut 130. The nut130 may be rotatable relative to the latch 132. In some embodiments,providing ring shaped grooves and allowing the nut 130 to rotaterelative to the latch 132 allows for the dose setting mechanism 116 torotate the ram 128 relative to the nut 130 and therefore axially movethe ram 128 as discussed further below. During assembly of the injectiondevice 110, the nut 130 is configured to couple to the latch 132 in oneof a plurality of positions along an axial length of the nut 130, eachof the plurality of positions along the axial length of the nut 130corresponding to one of the plurality of volumes of medicament for thefiring mechanism to expel.

The nut 130 may be configured to engage a stop fixed relative to thefluid delivery device 110 at the end of the delivery stroke as discussedbelow. As a result, the distance the ram 128 extends distally from thenut 130, in some embodiments, is set to correspond to the volume of thefluid reservoir 118 (e.g., the axial distance between the piston 120 andthe nut 130). For example, the position of the latch 132 relative to thenut 130 in the position illustrated in FIGS. 4B-4D corresponds to avolume of a 0.6 ml fluid reservoir 118. If a 0.4 ml fluid reservoir 118is used, then the nut 130 may be rotated distally down the ram 128 untilthe next higher indent 130 a of the nut 130 aligns with the projection132 a of the latch 132. If a 0.8 ml fluid reservoir 118 is used, thenthe nut 130 may be rotated proximally up the ram 128 until the nextlower indent 130 a of the nut 130 aligns with the projection 132 a ofthe latch 132.

The latch 132 may include a sleeve 132 d surrounding the nut 130 andaxially fixed relative to the fluid reservoir 118. The latch 132 mayinclude a pivot arm 132 c that is pivotably connected to the sleeve 132d and configured to radially move the projection 132 a out of the axialpath of the nut 130 in the firing or released position (see FIG. 9B). Inone embodiment, the pivot arm 132 c is prevented from pivoting in aninitial position by a radial stop 140 e (see FIG. 2 ). The latch 132 mayinclude a slanted surface 132 b that engages with a correspondingslanted surface 140 d in the released position (see also FIG. 17 ). Oncethe latch 132 is disengaged from the nut 130, the nut 130 and thethreadably engaged ram 128 are released axially and fired distally bythe biasing member 126. In other embodiments, the latch 132 and nut 130have the reverse mating relationship described above such that the latch132 includes a feature that engages with one of a plurality ofprojections from the nut 130.

Referring to FIG. 4B, the direct force of the biasing member 126 upontriggering may be borne by the latch 132. In an embodiment, the latch132 includes a stop 132 e to attenuate the shock resulting from thestoppage of the firing mechanism at the termination of the injectionstroke. The stop 132 e may be a radially inwardly extending flange. Atthe end of delivery stroke (see FIGS. 9B and 10B) the nut 130 may engagethe stop 132 e. In one embodiment, the stop 132 e includes a resilientfeature. In one embodiment, the resilient feature of the stop 132 eincludes a spring. In another embodiment, the resilient feature of thestop 132 e includes an elastomeric washer.

In one embodiment, setting the volume by coupling the nut 130 to thelatch 132 at one of a plurality of locations results in an adjustment ofthe spring force by biasing member 126. By moving the nut 130 axiallyrelative to the latch 132 to set the volume, the biasing member 126 maybe more compressed for the larger volumes and less compressed for thesmaller volumes. The rate of delivery for a larger dose may therefore behigher than the rate of delivery for a smaller dose resulting in agenerally equal amount of time to deliver each dose. In someembodiments, the delivery time is not equal for each dose but closer tobeing equal than if the rate of delivery was instead constant. Referringto Table 1 below for example, a dose of 1.0 ml may be delivered inapproximately 7-10 seconds and a dose of 0.6 ml may be delivered inapproximately 6-9 seconds. Such a configuration, where the variabilitybetween delivery times for each dose is minimized, may be desirable forcompliance. For example, a patient who starts a treatment at a lowervolume may be accustomed to waiting a certain amount of time to delivera dose and be inclined to wait the same amount of time even if thetreatment is adjusted to a higher volume. An amount of spring decay maybe selected such that any differences in injection time between volumesdo not result in improper use of the device.

TABLE 1 Range of delivery times Delivered Injection Vol. time range (ml)(sec) 1.0  7-10 0.8 7-9 0.6 6-8 0.4 5-8 0.2 4-7

It may be desirable to provide a spring with a spring force decay curvewhere such that the difference in injection time between the volumes issuch that the user does not perceive a significant difference.

In another embodiment, rather than or in addition to the nut 130 havinga plurality of predetermined positions, the volume setting mechanismincludes a ram extension (not shown) threadably coupled to the ram 128.The ram extension may be configured to extend the length of the ram 128to a plurality of axial positions during assembly corresponding to oneof the plurality of volumes of medicament for the firing mechanism toexpel.

Referring to FIG. 2 , the injection device 110 may include a dosesetting mechanism 116 configured to select a fraction of the one of theplurality of volumes of medicament that is injected from the injectionconduit 122 when the firing mechanism is actuated. The dose settingmechanism 116 may include a knob rotatably coupled to the housing. Inone embodiment, the dose setting mechanism 116 caps the proximal end ofthe housing 112. The dose setting mechanism 116 may include a gripportion 116 a for grasping by the patient. The grip portion 116 a mayinclude one or more features such as axially extending ribs 116 a forincreasing the frictional force between the dose setting mechanism 116and a user's hand during use. The dose setting mechanism 116 may includea dosage level portion 116 b having a plurality of dosage indicia 116 e.The dose setting mechanism 116 may include a shaft 116 c for coupling tothe ram 128.

Referring to FIGS. 3A-3D, the dose setting mechanism 116 is rotatablymoveable relative to the housing 112. In one embodiment, the dosesetting mechanism 116 is fixed axially relative to the housing 112. Thedose setting mechanism 116 may be rotatably fixed and axially moveablerelative to the ram 128. The proximal end 128 a of the ram 128 may havea keyed shape that corresponds to the shape of the inside surface 116 dof shaft 116 c of the dose setting mechanism 116 such that rotating thedose setting mechanism 116 rotates the ram 128, and due to the threadedconnection between the ram 128 and the axially retained nut 130, movesthe ram 128 distally and proximally depending on the direction ofrotation. When the dose setting mechanism 116 is rotated, indicia 116 ecorresponding to the position of the ram 128 may align with the window112 a in the housing 112 to display the selected dosage to the patient.In one embodiment, rotating the dose setting mechanism 116 to move theram 128 does not impact the position and force on the biasing member126. In some embodiments, the dose setting mechanism 116 includes aresistance and/or an audible click between selected dosages.

Referring to FIG. 6B, the biasing member 126 such as a spring may beuniform and configured to not buckle. In one embodiment, there is nodirect spring load on the ram 128 from the biasing member 126 in theinitial position. This allows for the ram 128 to be axially positionedduring dose setting without impacting the spring force allowing for thespring force to be the same for each different volume of medicament.

Referring to FIG. 2 , the injection device 110 may configured to preventresetting after the firing mechanism is actuated so as to prevent asubsequent injection of the medicament by the injector, therebyconfiguring the injection device 110 as a single-use injector. In oneembodiment, the injection device 110 includes a guard 140 that isslideably coupled to the housing 112. The injection device 110 mayinclude a biasing member 138 coupled to the guard and configured to biasthe guard 140 toward a distal end 110 a of the injection device 110. Theguard 140 may be configured to extend axially past the injection conduit122. In one embodiment, the guard 140 is configured to extend axiallypast the injection conduit 122 and lock axially relative to the housing112 after removing the injection conduit 122 from the patient.

A sleeve 134 may be coupled to the fluid reservoir 118. The sleeve 134may include a pair of diametrically opposed tabs 134 a extendingoutwardly in the radial direction. The housing 112 may include a frontretainer 136 coupled to the distal end of the housing 112. The frontretainer 136 may include a pair of axially extending slots configured toreceive the tabs 134 a of the sleeve 134. The safety cap 114 mayreleaseably couple to the front retainer 136. The biasing member 138 maybe positioned within the front retainer 136 and engage the distal end ofthe sleeve 134. The other end of the biasing member 138 may beconfigured to engage a flange proximate the distal end of the guard 140.The guard 140 may include a pair of diametrically opposed and axiallyextending slots 140 c for receiving the tabs 134 a. The axial range ofmotion of the guard 140 may be dictated by the ends of the slots 140 cof the guard 140 engaging the tabs 134 a of the sleeve 134. The guard140 and the sleeve 134 may include one or more openings 140 b, 134 brespectively for aligning with a window 112 a of the housing 112 toreveal the level of medicament in the fluid reservoir 118. The fluidreservoir 118 may include indicia that are visible through the window112 a so that the patient can verify that the appropriate volume ofmedicament is included in the injection device 110.

Referring to FIG. 8B, the firing mechanism may be automatically releasedbased on the position of the injection conduit 122 relative to thepatient. In one embodiment, retracting the guard 140 relative to theinjection conduit 122 releases the firing mechanism. In otherembodiments, the patient must actuate a button or another feature beforeor after retracting the guard 140, or in an embodiment not including aguard 140, in order to release the firing mechanism.

The injection device 110 may accommodate two injection volumeadjustments. This may help to minimize the amount of unused drug. Thefirst adjustment is set during assembly and sets the range of volume tobe delivered (e.g., the dosing range). The dosing range may varydepending on the fill volume in the fluid reservoir 118. This amount maybe set as part of the assembly process. In one embodiment, there arefour configurations or SKUs. Each SKU will represent a maximum volume offill to allow delivery of the maximum dose within that SKU (e.g., 0.8 to1.0 ml volume delivery to the patient; 0.6 to 0.8 ml volume delivery tothe patient; 0.4 to 0.6 ml volume delivery to the patient; and 0.2 to0.4 ml volume delivery to the patient). The second adjustment is set bythe user prior to injecting the medicament. The second volume adjustmentsets the dose, a fraction of the volume in the fluid reservoir 118, andthis dose to be delivered within the range allowed by the injectiondevice 110. In one embodiment, the user may adjust the dose, up anddown, until the injection is delivered.

Referring to FIGS. 5C-5F, the injection device 110 may be pre-primed forthe user. In one embodiment, priming the injection device 110 allows forplacing the ram 128 in a known position relative to the piston 120.Priming may be used to reduce an initial gap between the ram 128 and thepiston 120 and/or compression in the piston 120 to allow for tightcontrol of the dose expelled during triggering. Since the ram 128 movesa fixed (controlled based on the dose selected) displacement, minimizingthe variability associated with the starting position of the ram 128 andcontrolling the end position of the ram 128 allows for greater accuracyof the delivered dose. Also, by providing a device that is alreadyprimed, there may be greater assurance that the patient will get thecorrect dosing by eliminating a step that the user might have to do andtherefore eliminate an opportunity for the user to get this wrong.

The injection device 110 may be designed for assembly that eliminatesthe priming step. A filling process may be utilized to minimize airbubble in the fluid reservoir 118. Once the fluid reservoir 118 isinserted into a front assembly, including the safety cap 114, the frontretainer 136, the guard 140 and the sleeve 134, is coupled with a middleassembly including the ram 128, the nut 130 and the latch 132. Theconnection between the distal end 128 c of the ram and the piston 120may be fully secured by rotating the nut 130 relative to the ram 128.The nut 130 may include one or more keyed features 130 b (see FIG. 103 b) such as a radially extending slot for coupling to a tool. Once the ram128 and stopper 120 are sufficiently coupled, a rear assembly includingthe housing 114 may be positioned over the middle assembly and coupledto the front assembly and the dose mechanism 116 and biasing member 126may be coupled to the middle assembly and the housing.

In some embodiments, the injection device 110 is primed by the user.Syringes are commonly supplied to autoinjector manufacturers in a‘drug-prefilled’ state. The prefilling process fills the syringe withdrug, and may use various methods including a vacuum process thatattempts to remove as much air as possible inside the syringe chamberbefore a plug/stopper is placed, sealing the syringe. Bubble priming,whereby all or most of the air is expelled from the syringe chamberthrough the needle prior to injection, is extremely common in manualinjections: a bubble in an intravenous injection can cause an airembolism in a patient. Unfortunately, bubble priming is not as simple inan autoinjector and the presence of an air bubble is detrimental to theaccuracy & precision of an autoinjector's drug delivery mechanism, whichcommonly relies upon advancing a ram abutted to the piston a tightlycontrolled travel distance. The bubble cannot be removed (primed) fromthe syringe without removing the needle cap resulting in a breach of thesterile barrier.

When an appreciable force is applied to a syringe piston during aninjection, any bubbles remaining trapped within the syringe willcompress, or displace ejected fluid decreasing the injected volume. Thisis due to pressure induced by the ram, the incompressible nature ofliquids, and compressibility of gas. A steady-state pressure equilibriumis then reached while the liquid drug is ejected until the ram reachesthe end of its stroke. At the end of the ram stroke, any previouslycompressed gasses will expand to equilibrium with the ambient. The rateupon which the gas expands is variable and dependent upon the ram force,the viscosity of the liquid, bubble size, needle lumen size and length,and the ambient pressure. As the bubble pressure approaches ambient, therate of fluid expulsion decays, increasing injection time (e.g.,preferably less than 10 seconds) for injectors with combined viscousdrug liquid and small needle lumens. As delivered volume is related tothe travel of the syringe plunger, the amount of liquid drug that isencompassed within this travel distance is required to be constant toallow accurate dispensing of drug.

In order to bubble prime the injection device 110, the injection device110 may be configured to be primed by the user by pointing the distalend 110 a upward and advancing the ram 128 relative to the fluidreservoir 118. By pointing the distal end 110 a of the injection device110 upward, buoyancy of the bubble positions it directly adjacent to theproximal end of the needle 122. Depending upon the viscosity of theliquid, a slight tapping of the injection device 110 may be required. Insome embodiments, the bubble may be observed through the window 112 b inthe housing 112.

In one embodiment, the injection device 110 is configured such thatremoving the safety cap 114 causes the ram 128 to advance a nominalpredetermined distance, expelling the bubble and potentially a smallamount of liquid from the needle 122. For example, a spacer may beprovided between the latch 132 and the proximal flanged end of the fluidreservoir 118.

Referring to FIG. 36 , in some embodiments, the ram 128 is expanded topreload the piston 120. In one embodiment, the ram 128 includes two ormore nesting elements. In one embodiment, a torsional spring 142 isnested in an outer ram 144. The torsional spring 142 may have a keyedrod 146 passing completely through the torsional spring, androtationally constrained to the torsional spring. The keyed rod 146 maybe locked by a removable release pin 148 extending from the distal end110 b of the injection device 110 and inserted into a keyed slot 150 ofan inner ram 152 on the other end. The release pin may constrain thetorsional spring until use. Upon removal, the torsional spring willrotate the inner ram relative to the outer ram, extending the inner ramto release the bubble (or provide a preload immediately prior to bubbleexpulsion).

Annular or partially annular teeth in the nested ram elements mayinterlock, (e.g., internal teeth on the outer cylinder/external teeth orslots on the inner cylinder) allowing only one way relative movement ofthe nested ram elements, inducing the ram 128 to extend and preload thepiston 120. In one embodiment, instead of teeth, the nested ram elementsare internally/externally threaded, allowing preload from rotation of adevice element. In one embodiment, the ram 128 includes a three part ram128 comprised of both one way-tooth interaction and threadedinteractions.

The spacer or ram 128 may be coupled to the safety cap 114 such thatremoving the safety cap 114 removes the spacer or expands the ram 128and preloading a force onto the piston 120. In other embodiments, theuser actuates a trigger such as by pulling a pin, flipping a switch,pushing a button, that pulls the spacer out of the loading stack ordevice entirely or expands the ram 128. In one embodiment, setting thedose setting mechanism 116 automatically preloads piston 120. Forexample, instructions or indication to twist the dose setting mechanism116 may be visible through window 112 a even to set the injection device110 to the maximum dose. This initial twist of the dose settingmechanism 116 may be used to extend the ram 128 to prime the injectiondevice 110. The dosage indicia 116 e may be oriented (rotated 180degrees from example shown in FIG. 1 ) such that the number is readablewhen the distal end 110 a of the injection device 110 is pointed up.

In one embodiment, removal of the safety cap 114 allows the guard 140,under spring load, to extend a predetermined distance. This movementallows a second spring loaded assembly connected to the ram to advance anominal distance to a predetermined set-point, inducing an axial preloadon the piston 120 (see FIGS. 32 a and 32 b as discussed further below).In one embodiment, the guard 140 is under a lower spring force than thefiring mechanism such that coupling the priming of the injection device110 to the guard 140 allows for the priming force to be controlled moreprecisely.

Once the safety cap 114 is removed, the fluid reservoir 118 may bebubble primed and ready for injection. A liquid receiver, such as apiece of absorbent material, may be positioned adjacent to the needle122 toward the distal end 110 a of the injection device 110 to captureany expelled liquid drug during priming. The liquid receiver may be incircumferential association with the needle 122 and may be attached tothe housing 112, safety cap 114 or both (e.g., 2 pieces of absorbentmaterial).

Following assembly, the injection device 110 is ready for use. Referringto FIG. 6B, during use of an exemplary embodiment, the user is awarewhat volume of medicament is provided in the injection device 110 andmay verify by looking at the fluid reservoir 118 through the window 112b in the housing (see FIG. 1 ). The user then selects the desired doseto be delivered, either all or a fraction of the volume of the fluidreservoir 118, by rotating the dose setting mechanism 116 relative tothe housing 112. The user may verify that the appropriate dosage isselecting by viewing the dosage amount indicated by the indicia visiblethrough window 112 a in the housing (see FIG. 1 ). FIG. 7B shows theinjection device in a minimum dosage selection such that the ram 128 ispulled back from piston 120. The distance between the piston 120 and theram 128 is the distance that will remain between the piston 120 and thedistal end of the fluid reservoir 118. The medicament remaining in thefluid reservoir following the injection is not delivered and may bediscarded.

Referring to FIG. 8B, once the dosage is set, the user removes thesafety cap 114 (see FIG. 7B) from the front retainer 136 by pulling ortwisting the safety cap 114 relative to the front retainer 136. Anypriming is conducted if necessary, and the injection device 110 is readyfor injection. The patient may then press the distal end of the guard140 against their skin, retracting the guard 140 proximally until theneedle 122 penetrates the skin surface and the proximal end 140 d of theguard 140 contacts the slanted surface 132 b of the latch 132.

Referring to FIG. 9B, once the proximal end 140 d of the guard contactsthe slanted surface 132 b of the latch 132, the guard is furtherretracted to its fully retracted position, moving the stop 140 e off ofthe pivot arm 132 c of the latch and the proximal end 140 d of the guardforces against the slanted surface 132 b to pivot the pivot arm 132 cand release the projection 132 a of the latch 132 from the indentation130 a of the nut 130.

Referring to FIG. 10B, with the latch 132 released from the nut 130, thebiasing member 126 is no longer restrained and the ram 128 and nut 130are fired toward the distal end, urging the piston 120 distally anddelivering the dose of medicament to the patient through the injectionconduit 122.

Referring to FIGS. 12 a and 12 b , after the dose is delivered, thehousing 112 is pulled away from the patient, pulling the needle 122 fromthe patient and allowing the biasing member 138 to urge the guard 140distally past the end of the needle 122. A retaining member retains theguard 122 to lock the guard 140 relative to the needle 122 preventingfurther use of the injection device 110. The injection device 110 maythen be safely discarded.

Referring to the drawings in detail, wherein like reference numeralsindicate like elements throughout, there is shown in FIGS. 19A-35B aninjection device, generally designated 210, a second exemplaryembodiment of the present invention. Various embodiments of theinjection device 210 are described in further detail below in referenceto the exemplary embodiment shown in the figures. One or more of theembodiments discussed in reference to the injection device 210 describedbelow may be combined with one or more desirable features of theembodiments discussed in reference to the injection device 110 describedabove.

The injection device 210 is configured to deliver a selected amount ofone of a plurality of predetermined volumes of medicament to a patient.The injection device 210 is assembled using one of a plurality of fluidreservoirs 218 and the dose that is ultimately delivered to the patientis equal to or less than the full amount contained in the injectiondevice 210. This allows for the injection device 210 to accept a fluidcartridge, prefilled syringe or similar container filled to differentvolumes and/or accept multiples sizes of containers and allow for theuser to select how much of the fluid in the fluid container to deliver.Such flexibility allows for one device to be adapted for multiplemedicament volumes and ultimately reduces the amount of wastedmedicament.

For example, a typical injection device may have a volume of 1.0 ml toencompass the range of potential dosages needed. A patient who isprovided a 1.0 ml device but only needs a dosage of 0.5 ml, would leavea residual volume of 0.5 ml in the discarded device. Instead, thepatient, requiring a dosage of 0.5 ml, can be provided a 1.0 mlinjection device 210 containing 0.6 ml of fluid, resulting in a residualvolume of only 0.1 ml in the discarded device. By allowing adjustment ofthe volume, the manufacturer can easily set the injection device 210 toone of a plurality of volumes to divide up the range of dosagesselectable by a patient and reduce the amount of residual fluid left inthe discarded device.

The injection device 210 includes an actuator for driving fluid from theinjection device 210 into the patient. In some embodiments, the actuatoris automatically actuated as a result of positioning the injectiondevice 210 relative to the skin surface, also referred to as anauto-injection device. The injection device 210 may include a needle. Inother embodiments, the injection device does not include a needle andthe injection port of the fluid chamber preferably defines a fluidpathway in fluid communication with the fluid chamber for injectingmedicament as a jet from the chamber through the port to the injectionlocation. An example of a suitable needle-free jet nozzle arrangement isdisclosed in U.S. Pat. No. 6,309,371, which is incorporated by referencein its entirety.

As disclosed in further detail below, in some embodiments, the injectiondevice 210 includes a firing mechanism having an actuator, a volumesetting mechanism configured to be selectively preset during assembly toone of a plurality of positions based on a maximum volume of medicamentto be delivered to the patient (e.g., one of a 0.4 ml, 0.6 ml, 0.8 ml or1.0 ml prefilled syringe) and a dose setting mechanism configured to beselectably adjusted upon use, independent of the preset of the volumesetting mechanism, to select a fraction of the maximum volume ofmedicament to be delivered to the patient (e.g., a 0.2 ml to 0.4 ml dosefor a 0.4 ml syringe).

Referring to FIGS. 19A-19B, the injection device 210 may include ahousing 212. The housing 212 extends along a longitudinal axis A and isconfigured to be held in one hand of a patient or caregiver to deliverthe dose of medicament to the patient. In one embodiment, the housing212 is cylindrical. In other embodiments, the cross sectional shape ofthe housing 212 is elliptical, triangular, square or any other desiredshape. The housing 212 may include one or more windows 212 a, 212 b forviewing components of the injection device 210 contained within thehousing 212. The windows 212 a, 212 b may be covered with a transparentmaterial. Windows 212 a, 212 b may allow the viewing of the fluidreservoir within the housing 212. The window 212 a, 212 b may also allowviewing of the preset volume that has been chosen. In anotherembodiment, the window 212 a, 212 b allows viewing that the device isready for use. In another embodiment, the window 212 a, 212 b allows theviewing the injection is complete. Other uses of a window to allowviewing internal aspects of the injection device are anticipated. In anembodiment, the window 212 a, 212 b allows viewing of injection deviceinternal components that assist in administering an injection. In oneembodiment, the housing 212 is comprised partially or entirely of atransparent material.

Referring to FIGS. 19C-19D, the housing 212 is configured to house afluid reservoir 218 having one of a plurality of volumes of medicament.The volume of the fluid reservoir 218 is selected before assembling theinjection device 210. In one embodiment, the volume of the selectedfluid reservoir 218 is based on the desired maximum dose that thepatient can inject. In one embodiment, the injection device 210 isconfigured to receive one sized container or syringe having a fluidreservoir 218 to accommodate a plurality (e.g., six) different maximumvolumes for injection. In other embodiments, the injection device 210 isconfigured to receive a container having two, three, four, five, sevenor more different maximum volumes for injection. In other embodiments,the injection device 210 is configured to receive six differently sizedcontainers having fluid reservoirs 118. In other embodiments, theinjection device 210 is configured to receive two, three, four, five,six, seven or more differently sized containers having fluid reservoirs218. In one embodiment, the fluid reservoir 218 contains one of 0.4 ml,0.6 ml, 0.8 ml, or 1.0 ml of medicament. In other embodiments, the fluidreservoir 218 contains other amounts of medicament such as one or moreof the following amounts: 0.04 ml, 0.05 ml, 0.06 ml, 0.07 ml, 0.08 ml,0.09 ml, 0.1 ml, 0.2 ml, 0.3 ml, 0.4 ml, 0.5 ml, 0.6 ml, 0.7 ml, 0.8 ml0.9 ml, 1.0 ml, 1.1 ml, 1.2 ml, 1.3 ml, 1.4 ml, 1.5 ml, 1.6 ml, 1.7 ml,1.8 ml, 1.9 ml, 2.0 ml, greater than 2.0 ml, less than 0.010 ml and anyamount between these numbers. In one embodiment, the fluid reservoir 218includes a prefilled syringe having a piston 220 forming a sliding sealat a proximal end. An injection conduit 222 is fluidly coupled to thefluid reservoir defining a fluid pathway from the fluid reservoir 218 tothe patient. In one embodiment, the injection conduit 222 is a needle.The needle 222 may be staked to the prefilled syringe.

The needle 222 may be covered by a needle cap 224 in the stowed orinitial position. The needle cap 224 may include an elastomeric materialfor sealing and protecting the needle 222 in the initial position. Theinjection device 210 may further or alternatively include a safety cap214 that is releaseably coupled to a distal end 210 a of the injectiondevice 210. The safety cap 214 covers the injection conduit 218 in theinitial position to prevent contamination and accidental needle sticksor actuation of the actuator. The safety cap 214 may be coupled to theneedle cap 224 such that removing the safety cap 214 from the housing212 also strips the needle cap 224 from the needle 222 and exposes theneedle 222.

The injection device 210 may include a firing mechanism coupled to thefluid reservoir 218 and configured to expel the medicament from thefluid reservoir 218 through the injection conduit 222. The injectiondevice 210 may include an actuator such as a biasing member 226. In oneembodiment, the biasing member 226 includes a compression spring. Inanother embodiment, the actuator is pneumatically driven. The biasingmember 226 may be operatively associated with a ram 228 extending alongthe longitudinal axis A. The ram 228 may include a keyed shaft 228 c(see FIG. 21B). The ram 228 may be coupled to the fluid reservoir 218such that the biasing member 226 urges the ram 228 to compress the fluidreservoir 218 and deliver the medicament to the patient through theinjection conduit 222. In one embodiment, the ram 228 is coupled to thepiston 220. The ram 228 may include a prime screw 242 extending distallyfrom the end of the ram 228 at selectively adjustable distances tomaintain contact between the ram 228 and the piston 220 for primingpurposes as discussed in further detail below.

Referring to FIGS. 21A-21C and 22A-22F, the volume setting mechanism maybe set or configured during assembly of the injection device 210 toproperly deliver the one of the plurality of volumes of medicamentselected as the fluid reservoir 218. The volume setting mechanism mayinclude a latch 232, a slot stop or stop 230 and a retainer 230 a. Theretainer 230 a may be configured to retain the latch 232 relative to theslot stop 230. In one embodiment, the latch 232 is releaseably retainedin the axial direction against a force of the biasing member 226 in aninitial position by the retainer 230 a. The latch 232 may include aradial projection such as a flange 232 a configured to engage the end ofthe biasing member 226 (see FIG. 19C). The latch 232 may be axiallyfixed and rotatably coupled to the ram 228. The proximal end of the ram228 may include a collar 228 d that is rotatably received in acorresponding ring shaped groove in the latch 232. The slot stop 230 maybe axially and rotatably fixed relative to the fluid reservoir 218. Theram 228 may include a radially extending wing 228 b fixed to the ram228. In other embodiments, the ram 228 includes two or more radiallyextending wings. As discussed further below, the slot stop 230 may beconfigured to set the axial position of the ram 228 relative to thefluid reservoir 218 and limit how far the ram 228 is permitted to travelrelative to the fluid reservoir 218.

Referring to FIGS. 21A-21C, the latch 232 may include a plurality ofradially extending features 232 b, such as apertures, indents and/orprojections, each configured to engage with the retainer 230 a. Each ofthe plurality of radially extending features 232 b may be axially spacedfrom one another. In one embodiment, such a configuration positions thedistal end of the ram 228 relative to the fluid reservoir 218. Duringassembly of the injection device 210, the retainer 230 a is configuredto couple to the latch 232 in one of a plurality of positions along anaxial length of the latch 232, each of the plurality of positions alongthe axial length of the latch 232 corresponding to one of the pluralityof volumes of medicament of the fluid reservoir 218 for the firingmechanism to expel. In one embodiment, the latch 232 includes anadditional set of radially extending features 232 b closest to theproximal end to retain the latch 232 relative to the slot stop 230 atthe end of delivery.

Referring to FIG. 37 , another embodiment of the latch 332 is shown. Thelatch 332 may include a single, radially extending feature 332 bconfigured to engage with the retainer 230 a. In one embodiment, theradially extending feature 332 b is a window or cut-out. The axial depthor height of the radially extending feature 332 b may be predetermined,and one of a plurality of latches 332 is selected based on the axialdepth or height of its radially extending feature 332 b. The latch 332that is selected will depend on the desired one of the plurality ofvolumes of medicament of the fluid reservoir 218 for the firingmechanism to expel. The latch 332 may include one or more alignmentfeatures 332 d that engage a corresponding feature of the housing toprevent the latch 332 from rotating relative to the housing duringfiring. In one embodiment, the alignment features 332 d include aplurality of opposed and axially spaced projections that are configuredto engage a rib extending axially and projecting radially inward fromthe housing.

Referring to FIGS. 21A-21C, the wing 228 b of the ram 228 may beconfigured to engage a stop fixed relative to the fluid delivery device210 at the end of the delivery stroke as discussed below. As a result,the distance the ram 228 extends distally from a bottom surface 230 h ofthe slot stop 230, in some embodiments, is set to correspond to thevolume of the fluid reservoir 218 (e.g., the axial distance between thepiston 220 and the bottom surface 230 h of the slot stop 230). Forexample, the position of the latch 232 relative to the slot stop 230 inthe maximum position illustrated in FIGS. 21A-21C corresponds to avolume of a 1.0 ml fluid reservoir 218. If a 0.8 ml fluid reservoir 218is used for example, then the slot stop 230 may be move proximallyrelative to the latch 232 to engage the projection 230 c of the retainer230 a with the next proximal radially extending feature 232 b of thelatch 232 and extend the ram 228 further toward the distal end 210 a ofthe injection device 210.

Referring to FIGS. 22A-22F, the retainer 230 a may be integrally formedwith the slot stop 230. In other embodiments, the retainer 230 a is aseparate component from slot stop 230. The retainer 230 a may be acantilever arm. In one embodiment the retainer 230 a has one or morecircumferentially extending protections to form an upside down capitalletter T or Y shape. In one embodiment, two or more retainers 230 a areprovided. In one embodiment, two diametrically opposed retainers 230 aare provided. The retainer 230 a may be configured to radially deflectinward about an inflection point 230 e. In one embodiment, inflectionpoint 230 e includes a groove or recess to help facility bending of thematerial. The retainer 230 a may include a projection 230 c that engagesa corresponding radially extending feature 232 b (see FIG. 21A) toprevent axial movement of the latch 232 in the initial position. Theprojection 230 c may include a sloped top surface 230 d to helpfacilitate translating the axial force exerted on the retainer 230 ainto a radial deflection of the retainer 230 a to move the projection230 c from interfering with axial motion of the latch 232 in thetriggered or released position.

Once the latch retainer 230 a is disengaged from the latch 232, thelatch 232 and ram 228 are released axially and fired distally by thebiasing member 226. In other embodiments, the latch 232 and retainer 230a have the reverse mating relationship to the configuration describedabove such that the radially extending features 232 b are protrusionsthat are engageable by an indent or aperture in the retainer 230 a.

In one embodiment, setting the volume by coupling the slot stop 230 tothe latch 232 at one of a plurality of locations results in anadjustment of the spring force by biasing member 226. By moving the slotstop 230 axially relative to the latch 232 to set the volume, thebiasing member 226 may be more compressed for the larger volumes andless compressed for the smaller volumes. The rate of delivery for alarger dose may therefore be higher than the rate of delivery for asmaller dose resulting in a generally equal amount of time to delivereach dose. In some embodiments, the delivery time is not equal for eachdose but closer to being equal than if the rate of delivery was insteadconstant. Referring to FIG. 2 for example, a dose of 1.0 ml may bedelivered in approximately 7-10 seconds and a dose of 0.6 ml may bedelivered in approximately 6-9 seconds. Such a configuration, where thevariability between delivery times for each dose is minimized, may bedesirable for compliance. For example, a patient who starts a treatmentat a lower volume may be accustomed to waiting a certain amount of timeto deliver a dose and be inclined to wait the same amount of time evenif the treatment is adjusted to a higher volume. An amount of springdecay may be selected such that any differences in injection timebetween volumes do not result in improper use of the device.

TABLE 2 Range of delivery times Delivered Injection Vol. time range (ml)(sec) 1.0  7-10 0.8 7-9 0.6 6-8 0.4 5-8 0.2 4-7

It may be desirable to provide a spring with a spring force decay curvewhere such that the difference in injection time between the volumes issuch that the user does not perceive a significant difference.

Referring to FIGS. 19C-20B, the injection device 210 may include a dosesetting mechanism 216 configured to select a fraction of the one of theplurality of volumes of medicament that is injected from the injectionconduit 222 when the firing mechanism is actuated. The dose settingmechanism 216 may include a knob rotatably coupled to the housing. Inone embodiment, the dose setting mechanism 216 caps the proximal end ofthe housing 212. The dose setting mechanism 216 may include a gripportion 216 a for grasping by the patient. The grip portion 216 a mayinclude one or more features such as axially extending and radiallyprojecting ribs 216 a for increasing the frictional force between thedose setting mechanism 216 and a user's hand during use. The dosesetting mechanism 216 may include a dosage level portion 216 b having aplurality of dosage indicia 216 e. The dose setting mechanism 216 mayinclude a shaft 216 d for coupling to the ram 228.

Referring to FIGS. 19C-19D and 24A-24E, the dose setting mechanism 216may be rotatably moveable relative to the housing 212. In oneembodiment, the dose setting mechanism 216 is fixed axially relative tothe housing 212. The dose setting mechanism 216 may be rotatably fixedand axially moveable relative to the ram 228. The interior shaft 228 c(see FIGS. 21B and 23 ) of the ram 228 may have a keyed shape thatcorresponds to the shape (such as projections 216 f) of the shaft 216 dof the dose setting mechanism 216 such that rotating the dose settingmechanism 216 rotates the ram 228, and rotates the wing 228 b relativeto the slot stop 230 (see FIG. 28C). When the dose setting mechanism 216is rotated, indicia 216 e corresponding to the radial position of thewing 228 b may align with the window 212 a in the housing 212 to displaythe selected dosage to the patient. In one embodiment, rotating the dosesetting mechanism 216 to rotate the ram 228 does not impact the positionand force on the biasing member 226. In some embodiments, the dosesetting mechanism 216 includes a resistance and/or an audible clickbetween selected dosages.

Referring to FIGS. 22A-22F, the slot stop 230 may include a body 230 f.The body 230 f may be held stationary with respect to the fluidreservoir 218. In one embodiment, the body 230 f includes a hole 230 gextending there through to allow the ram 228 to pass through the slotstop 230 (see FIG. 21B). The slot stop 230 may include a plurality ofaxially extending and radially projecting slots 230 b. In oneembodiment, the slots 230 b are open toward the hole 230 g. The slots230 b may be sized and configured to receive the wing 228 b in the firedposition. The slots 230 b may have different axial depths such that thewing 228 b is stopped different distances from a bottom surface 230 h ofthe body 230 f and therefore stops the distal end of the piston atdifferent distances relative to the fluid reservoir 218. The wing 228 bmay include a pointed bottom edge 228 c and/or the slot stop 230 mayinclude pointed spaces between each of the slots 230 b to help ensurethat the wing 228 b is guided into the appropriate slot 230 b. In oneembodiment, the slots 230 b have an increasing axial depth from one slot230 b to an adjacent slot 230 b moving around the hole 230 g. In otherembodiments, every other slot 230 b has an increasing axial depth if twodiametrically opposed wings 228 b are provided, for example.

Referring to FIGS. 19C-21C, the injection device 210 may be pre-primedfor the user. In one embodiment, priming the injection device 210 allowsfor placing the ram 228 in a known position relative to the piston 220.Priming may be used to reduce an initial gap between the ram 228 and thepiston 220 and/or compression in the piston 220 to allow for tightcontrol of the dose expelled during triggering. Since the ram 228 movesa fixed (controlled based on the dose selected) displacement, minimizingthe variability associated with the starting position of the ram 228 andcontrolling the end position of the ram 228 allows for greater accuracyof the delivered dose. Also, by providing a device that is alreadyprimed, there may be greater assurance that the patient will get thecorrect dosing by eliminating a step that the user might have to do andtherefore eliminate an opportunity for the user to get this wrong. Theinjection device 210 may be designed for assembly that eliminates thepriming step. A filling process may be utilized to minimize air bubblein the fluid reservoir 218. Once the fluid reservoir 218 is insertedinto a front assembly, including the safety cap 214, the front retainer236, the guard 240 and the sleeve 234, is coupled with a middle assemblyincluding the ram 228, the latch 232 and the slot stop 230 (selectivelycoupled to the desired axial position on the latch 232) which is thencoupled with a rear assembly including the biasing member 226, thehousing 212 and the dose setting mechanism 216.

After setting the volume setting mechanism and before attaching orsealing off the dose setting mechanism, the ram 228 may be primed. Inone embodiment, the ram 228 is primed using a prime screw 242. The primescrew 242 may be threadably attached to the ram 228 to adjust how faraxially the prime screw 242 extends from the ram 228. The prime screw242 may include a keyed feature 242 b such that a corresponding tool maybe inserted through the shaft 228 c of the ram 228 to rotate the primescrew 242 and adjust the position of the distal end 242 a of the primescrew 242 relative to the piston 220. In one embodiment, the distal end242 a is configured to be in contact with the piston 220 in the initialposition independent of the position of the dose mechanism 216.

In one embodiment, the distal end 242 a of the prime screw 242 is incontact with the piston 220 in the initial position such that the ram228 does not move relative to piston 220 during triggering. Byeliminating an axial space between the piston 220 and the ram 228 in theinitial position, the ram 228 may be prevented from dynamicallyimpacting the piston 220 once the injection device 210 has been fired,referred to as “shock loading”. In some embodiments, the patient mayfeel or hear the impact between the ram 228 and the piston 220 if thereis shock loading and/or the impact may potentially damage the syringe.In certain embodiments, a gap between the ram 228 and the piston 220 isprovided if desired.

Referring to FIGS. 32-35B, in some embodiments, the injection device 210is primed by the user. Syringes are commonly supplied to autoinjectormanufacturers in a ‘drug-prefilled’ state. The prefilling process fillsthe syringe with drug, and may use various methods including a vacuumprocess that attempts to remove as much air as possible inside thesyringe chamber before a plug/stopper is placed, sealing the syringe.Bubble priming, whereby all or most of the air is expelled from thesyringe chamber through the needle prior to injection, is extremelycommon in manual injections: a bubble in an intravenous injection cancause an air embolism in a patient. Unfortunately, bubble priming is notas simple in an autoinjector and the presence of an air bubble isdetrimental to the accuracy and precision of an autoinjector's drugdelivery mechanism, which commonly relies upon advancing a ram abuttedto the piston a tightly controlled travel distance. The bubble cannot beremoved (primed) from the syringe without removing the needle capresulting in a breach of the sterile barrier.

When an appreciable force is applied to a syringe piston during aninjection, any bubbles remaining trapped within the syringe willcompress, or displace ejected fluid decreasing the injected volume. Thisis due to pressure induced by the ram, the incompressible nature ofliquids, and compressibility of gas. A steady-state pressure equilibriumis then reached while the liquid drug is ejected until the ram reachesthe end of its stroke. At the end of the ram stroke, any previouslycompressed gasses will expand to equilibrium with the ambient. The rateupon which the gas expands is variable and dependent upon the ram force,the viscosity of the liquid, bubble size, needle lumen size and length,and the ambient pressure. As the bubble pressure approaches ambient, therate of fluid expulsion decays, increasing injection time (e.g.,preferably less than 10 seconds) for injectors with combined viscousdrug liquid and small needle lumens. As delivered volume is related tothe travel of the syringe plunger, the amount of liquid drug that isencompassed within this travel distance is required to be constant toallow accurate dispensing of drug.

In order to bubble prime the injection device 210, the injection device210 may be configured to be primed by the user by pointing the distalend 210 a upward and advancing the ram 228 relative to the fluidreservoir 218. By pointing the distal end 210 a of the injection device210 upward, buoyancy of the bubble positions it directly adjacent to theproximal end of the needle 222. Depending upon the viscosity of theliquid, a slight tapping of the injection device 210 may be required. Insome embodiments, the bubble may be observed through the window 212 b inthe housing 212.

Referring to FIGS. 32-33D, in one embodiment, the injection device 210is configured such that removing the safety cap 214 causes the ram 228to advance a nominal predetermined distance, expelling the bubble fromthe fluid reservoir 218 and potentially a small amount of liquid fromthe needle 222. For example, a spacer 214 a may be provided between thelatch 232 and the proximal flanged end of the fluid reservoir 218. Inone embodiment, the spacer 214 a is a sleeve that extends proximallyfrom the safety cap 214 to retain the slot stop 230 a distance G from aproximal end of the fluid reservoir 218. Removing the spacer 214 aallows the firing mechanism, including the ram 228, to advance thedistance G and have the slot stop 230 abut against the proximal end ofthe fluid reservoir 218 or whatever feature is coupled to the proximalend of the fluid reservoir 218 such as a bumper.

Referring to FIG. 36 , in some embodiments, the ram 228 is expanded topreload the piston 220. In one embodiment, the ram 228 includes two ormore nesting elements. In one embodiment, a torsional spring 142 isnested in an outer ram 144. The torsional spring 142 may have a keyedrod 146 passing completely through the torsional spring, androtationally constrained to the torsional spring. The keyed rod 146 maybe locked by a removable release pin 148 extending from the distal end210 b of the injection device 210 and inserted into a keyed slot 150 ofan inner ram 152 on the other end. The release pin may constrain thetorsional spring until use. Upon removal, the torsional spring willrotate the inner ram relative to the outer ram, extending the inner ramto release the bubble (or provide a preload immediately prior to bubbleexpulsion).

Annular or partially annular teeth in the nested ram elements mayinterlock, (e.g., internal teeth on the outer cylinder/external teeth orslots on the inner cylinder) allowing only one way relative movement ofthe nested ram elements, inducing the ram 228 to extend and preload thepiston 220. In one embodiment, instead of teeth, the nested ram elementsare internally/externally threaded, allowing preload from rotation of adevice element. In one embodiment, the ram 228 includes a three part ram228 comprised of both one way-tooth interaction and threadedinteractions.

The spacer or ram 228 may be coupled to the safety cap 214 such thatremoving the safety cap 214 removes the spacer or expands the ram 228and preloads a force onto the piston 220. In other embodiments, the useractuates a trigger such as by pulling a pin 244 (see FIGS. 34 a -34B),flipping a switch, pushing a button, that pulls the spacer out of theloading stack or device entirely or expands the ram 228. In oneembodiment, setting the dose setting mechanism 216 automaticallypreloads piston 220. For example, instructions or indication to twistthe dose setting mechanism 216 may be visible through window 212 a evento set the injection device 210 to the maximum dose. This initial twistof the dose setting mechanism 216 may be used to extend the ram 228 toprime the injection device 210. The dosage indicia 216 e may be oriented(rotated 180 degrees from example shown in FIG. 19B) such that thenumber is readable when the distal end 210 a of the injection device 210is pointed up.

Referring to FIGS. 35 a and 35 b , in one embodiment, removal of thesafety cap 214 allows the guard 240, under spring load, to extend apredetermined distance. This movement allows for one or more prime arms230 i to deflect radially inward and cause the second spring loadedassembly connected to the ram to advance a nominal distance to apredetermined set-point, inducing an axial preload on the piston 220. Inone embodiment, the guard 240 is under a lower spring force than thefiring mechanism such that coupling the priming of the injection device210 to the guard 240 allows for the priming force to be controlled moreprecisely.

Once the safety cap 214 is removed, the fluid reservoir 218 may bebubble primed and ready for injection. A liquid receiver, such as apiece of absorbent material, may be positioned adjacent to the needle222 toward the distal end 210 a of the injection device 210 to captureany expelled liquid drug during priming. The liquid receiver may be incircumferential association with the needle 222 and may be attached tothe housing 212, safety cap 214 or both (e.g., 2 pieces of absorbentmaterial).

Referring to FIGS. 19C and 27A-27D, the injection device 210 mayconfigured to prevent resetting after the firing mechanism is actuatedso as to prevent a subsequent injection of the medicament by theinjector, thereby configuring the injection device 210 as a single-useinjector. In one embodiment, the injection device 210 includes a guard240 that is slideably coupled to the housing 212. The injection device210 may include a biasing member 238 coupled to the guard 240 andconfigured to bias the guard 240 toward a distal end 210 a of theinjection device 210. The guard 240 may be configured to extend axiallypast the injection conduit 222. In one embodiment, the guard 240 isconfigured to extend axially past the injection conduit 222 and lockaxially relative to the housing 212 after removing the injection conduit222 from the patient.

Referring to FIGS. 20A-20B, a sleeve 234 may be coupled to the fluidreservoir 218. The sleeve 234 may include a pair of diametricallyopposed tabs 234 a extending outwardly in the radial direction. Thehousing 212 may include a front retainer 236 coupled to the distal endof the housing 212. The front retainer 236 may include a pair of axiallyextending slots 236 a configured to receive the tabs 234 a of the sleeve234. The safety cap 214 may releaseably couple to the front retainer236. The biasing member 238 may be positioned within the front retainer236 and engage the distal end of the sleeve 234. The other end of thebiasing member 238 may be configured to engage a flange proximate thedistal end of the guard 240. The guard 240 may include a pair ofdiametrically opposed and axially extending slots 240 c for receivingthe tabs 234 a. The axial range of motion of the guard 240 may bedictated by the ends of the slots 240 c of the guard 240 engaging thetabs 234 a of the sleeve 234. The guard 240 and the sleeve 234 mayinclude one or more openings 240 b, 234 b respectively for aligning witha window 212 b of the housing 212 to reveal the level of medicament inthe fluid reservoir 218. The fluid reservoir 218 may include indiciaand/or the level of fluid contained therein that are visible through thewindow 212 b so that the patient can verify that the appropriate volumeof medicament is included in the injection device 210.

Referring to FIGS. 24A-27D, the firing mechanism may be automaticallyreleased based on the position of the injection conduit 222 relative tothe patient. In one embodiment, retracting the guard 240 relative to theinjection conduit 222 releases the firing mechanism. In otherembodiment, the patient must actuate a button or another feature beforeor after retracting the guard 240, or in an embodiment not including aguard 240, in order to release the firing mechanism.

The injection device 210 may accommodate two injection volumeadjustments. This may help to minimize the amount of unused drug. Thefirst adjustment is set during assembly and sets the range of volume tobe delivered (e.g., the dosing range). The dosing range may varydepending on the fill volume in the fluid reservoir 218. This amount maybe set as part of the assembly process. In one embodiment, there arefour configurations or SKUs. Each SKU will represent a maximum volume offill to allow delivery of the maximum dose within that SKU (e.g., 0.8 to1.0 ml volume delivery to the patient; 0.6 to 0.8 ml volume delivery tothe patient; 0.4 to 0.6 ml volume delivery to the patient; and 0.2 to0.4 ml volume delivery to the patient). The second adjustment is set bythe user prior to injecting the medicament. The second volume adjustmentsets the dose, a fraction of the volume in the fluid reservoir 218, andthis dose to be delivered within the range allowed by the injectiondevice 210. In one embodiment, the user may adjust the dose, up anddown, until the injection is delivered.

Referring to FIGS. 24A-24E, during use of an exemplary embodiment, theuser is aware what volume of medicament is provided in the injectiondevice 210 and may verify by looking at the fluid reservoir 218 throughthe window 212 b in the housing (see FIGS. 20A-20B). The user thenselects the desired dose to be delivered, either all or a fraction ofthe volume of the fluid reservoir 218, by rotating the dose settingmechanism 216 relative to the housing 212. The user may verify that theappropriate dosage is selected by viewing the dosage amount indicated bythe indicia visible through window 212 a in the housing (see FIGS.20A-20B). FIGS. 28A-28C show the injection device in a minimum dosageselection such that the ram 228 is rotated such that the wing 228 balign with the shallowest slot 230 b. In one embodiment, the medicamentremaining in the fluid reservoir 218 following the injection is notdelivered and may be discarded.

Referring to FIGS. 25A-25E, once the dosage is set by the user, the userremoves the safety cap 214 from the front retainer 236 by pulling ortwisting the safety cap 214 relative to the front retainer 236 (see FIG.19C). Any priming is conducted if necessary, and the injection device110 is ready for injection. The patient may then press the distal end ofthe guard 240 against their skin retracting the guard 240 proximallyuntil the needle 222 penetrates the skin surface and the aperture 240 aaligns with the retainer 230 a.

Referring to FIGS. 25A-25E and 26A-26D, once the aperture 240 a isaligned with the retainer 230 a, the retainer 230 a is radially releasedand the axial force of the latch on the retainer 230 a pivots theprojection 230 c inwardly and out of the axial path of the latch 232allowing the biasing member 226 to distally extend the latch 232,causing the ram 228 to urge the piston 220 distally and deliver the doseof medicament to the patient through the injection conduit 222. Theshaft 216 d may extend a sufficient distance in the distal direction sothat the dose setting mechanism 216 remains rotatably fixed relative tothe ram 228. Since the ram 228 is rotatably fixed by the wing's 228 bengagement with the slot stop 230, the dose setting mechanism 216 isprevented from rotating in the fired position and ensuring that thedosage displayed through the window 212 a is the dosage that wasdelivered. If the dose setting mechanism 216 did not remain coupled tothe ram 228 in the fired position, then the dose setting mechanism 216may be able to rotate relative to the ram 228 and cause confusion as towhat dosage was delivered.

Referring to FIGS. 27A-27D, after the dose is delivered, the housing 212is pulled away from the patient, pulling the needle 222 from the patientand allowing the biasing member 238 to urge the guard 240 distally pastthe end of the needle 222. A retaining member retains the guard 240 tolock the guard 240 relative to the needle 222 preventing further use ofthe injection device 210. The injection device 210 may then be safelydiscarded. An exemplary lock-out system is described below.

Referring to the drawings in detail, wherein like reference numeralsindicate like elements throughout, there is shown in FIGS. 38A-42B alock-out system for an injection device, generally designated 310, athird exemplary embodiment of the present invention. Various embodimentsof the lock-out system are described in further detail below inreference to the exemplary embodiment shown in the figures. One or moreof the embodiments discussed in reference to the lock-out systemdescribed below may be combined with one or more desirable features ofthe embodiments discussed in reference to the injection devices 110 and210 described above.

Referring to FIGS. 38A and 40 , the front retainer 336, which is axiallyfixed relative to a housing and the fluid reservoir (not shown), mayinitially prevent the biasing member 338 (see FIGS. 43A and 43B) fromdistally extending the guard 340. The guard 340 however, may be free toretract relative to the front retainer 336 in the proximal direction.The front retainer 336 may include one or more arms 336 a that engagewith a corresponding stop 340 b of the guard 340. In one embodiment, thefront retainer 336 includes two pairs of arms 336 a (the front pair ofarms 336 a being visible in the drawings).

Referring to FIGS. 38B, 39A, 41A and 41B, the injection device 310 mayinclude a sleeve 334 fixed relative to the front retainer 336. Thesleeve 334 may include a radial projection 334 a. In one embodiment, thesleeve 334 includes a pair of diametrically opposed radial projections334 a (see FIG. 41B). In the initial position, the radial projection 334a may be positioned distally to the end of one or more arms 340 a of theguard 340. The radial projection 334 a may extend through a slot 340 cin the guard 340. As the guard 340 is retracted during an injection, theslot 340 c may be slid in a proximal direction relative to the radialprojection 334 a.

Referring to FIG. 42 , the latch may include one or more legs 332 c. Inone embodiment, the latch includes a pair of diametrically opposed legs332 c. The legs 332 c may be tapered distally. Once the firing mechanismis actuated and the latch 332 is released, the latch 332 is fireddistally by the biasing member 326 (see FIGS. 38A-38B). At the end ofthe delivery stroke, the legs 332 c of the latch 332 engage with thearms 336 a and flex the arms 335 a out of the axial path of the stops340 b (see FIG. 40 ) of the guard 340.

Referring to FIGS. 43A and 43B, once the arms 336 a are disengaged fromthe stops 340 b, the biasing member 338 extends the guard 340 distallyto cover the end of the needle. As the guard 340 extends, the slot 340 cof the guard is slid proximally relative to the radial projection 334 a.As the guard 340 extends past the initial position of the guard 340, thearms 340 a of the guard 340 extend over the radial projection 334 a ofthe sleeve 334. As the arms 340 a of the guard 340 extend over theradial projection 334 a, the ends of the arms 340 a flex away from oneanother until they engage with corresponding grooves 334 b (see FIGS.41A and 41B) and move closer to one another. The grooves 334 b of theradial projection 334 a are shaped to retain the arms 340 a in thelocked position and prevent the guard 340 from being urged in theproximal direction. In the locked position, the guard 340 is kept frombeing retracted in the proximal direction, preventing additionalexposure or use of the needle. The guard 340 may extend axially past theend of the needle to in both the initial and locked positions. In oneembodiment, the guard 340 is retracted to expose and allow insertion ofthe needle and is then extended to cover the needle. In one embodiment,the guard 340 extends further distally in the locked position relativeto the end of the needle than in the initial position.

It will be appreciated by those skilled in the art that changes could bemade to the exemplary embodiments shown and described above withoutdeparting from the broad inventive concepts thereof. It is understood,therefore, that this invention is not limited to the exemplaryembodiments shown and described, but it is intended to covermodifications within the spirit and scope of the present invention asdefined by the claims. For example, specific features of the exemplaryembodiments may or may not be part of the claimed invention and variousfeatures of the disclosed embodiments may be combined. Unlessspecifically set forth herein, the terms “a”, “an” and “the” are notlimited to one element but instead should be read as meaning “at leastone”.

It is to be understood that at least some of the figures anddescriptions of the invention have been simplified to focus on elementsthat are relevant for a clear understanding of the invention, whileeliminating, for purposes of clarity, other elements that those ofordinary skill in the art will appreciate may also comprise a portion ofthe invention. However, because such elements are well known in the art,and because they do not necessarily facilitate a better understanding ofthe invention, a description of such elements is not provided herein.

Further, to the extent that the methods of the present invention do notrely on the particular order of steps set forth herein, the particularorder of the steps should not be construed as limitation on the claims.Any claims directed to the methods of the present invention should notbe limited to the performance of their steps in the order written, andone skilled in the art can readily appreciate that the steps may bevaried and still remain within the spirit and scope of the presentinvention.

I/We claim:
 1. An injection device for injecting medicament in a patientcomprising: a housing configured to house a fluid reservoir having oneof a plurality of volumes of medicament; an injection conduit fluidlycoupled to the fluid reservoir configured to define a fluid pathway fromthe fluid reservoir to the patient; a firing mechanism coupled to thefluid reservoir and configured to expel the medicament from the fluidreservoir through the injection conduit; a volume setting mechanismcoupled to the firing mechanism and configured to be adjusted to selectthe one of the plurality of volumes of medicament for the firingmechanism to expel; and a dose setting mechanism configured to beadjusted to select a fraction of the one of the plurality of volumes ofmedicament that is injected from the injection conduit when the firingmechanism is actuated.
 2. The injection device of claim 1, wherein thevolume setting mechanism includes a nut and the firing mechanismincludes a ram and a biasing member, the nut being threadably coupled tothe ram, the nut being releaseably retained against a force of thebiasing member in an initial position by a latch.
 3. The injectiondevice of claim 2, wherein the nut includes a plurality of indentationseach configured to engage with a projection of the latch.
 4. Theinjection device of claim 3, wherein each of the plurality ofindentations includes a ring shaped groove extending circumferentiallyaround the nut.
 5. The injection device of claim 2 further comprising aguard that is slideably coupled to the housing, wherein the guard isconfigured to release the latch from the nut.
 6. The injection device ofclaim 5 further comprising a biasing member coupled to the guard andconfigured to bias the guard toward a distal end of the injectiondevice, the guard configured to extend axially past the injectionconduit.
 7. The injection device of claim 6, wherein the guard extendsfurther distally in a locked position than in an initial position. 8.The injection device of claim 2, wherein the nut is rotatable relativeto the latch.
 9. The injection device of claim 2, wherein the nut isconfigured to couple to the latch in one of a plurality of positionsalong an axial length of the nut, each of the plurality of positionsalong the axial length of the nut corresponding to one of the pluralityof volumes of medicament for the firing mechanism to expel.
 10. Theinjection device of claim 2, wherein the volume setting mechanismincludes a ram extension threadably coupled to the ram, the ramextension configured to extend the length of the ram to one of aplurality of positions corresponding to one of the plurality of volumesof medicament for the firing mechanism to expel.
 11. The injectiondevice of claim 2, wherein the ram is rotatably fixed and axiallymoveable relative to the dose setting mechanism.
 12. The injectiondevice of claim 2, wherein the latch includes a latch arm releaseablyretaining the nut in the initial position and a stop engaging the nut ina fired position, a distance between the latch arm and the stop beingfixed.
 13. The injection device of claim 1, wherein the volume settingmechanism includes a retainer and a latch and the firing mechanismincludes a ram and a biasing member, the latch being coupled between thebiasing member and the ram, the latch being retained against a force ofthe biasing member in an initial position by the retainer.
 14. Theinjection device of claim 13 further comprising: a stop having aplurality of axially extending and radially projecting slots eachextending a different axial depth, wherein the ram includes a wingextending radially from the ram and configured to engage one of theplurality of slots in a fired position.
 15. The injection device ofclaim 14, wherein the stop and the retainer are integrally connected.16. The injection device of claim 14, wherein the dose setting mechanismis rotatably coupled to the ram to radially align the wing with one ofthe plurality of slots in the initial position.
 17. The injection deviceof claim 13, wherein the ram includes a prime screw threadably coupledto the end of the ram, the prime screw configured to couple the ram to apiston.
 18. The injection device of claim 17, wherein the ram remains incontact with the piston independent of the position of the dose settingmechanism.
 19. The injection device of claim 13, wherein the latchincludes a plurality of axially spaced indentations each configured toengage with a projection of the retainer.
 20. The injection device ofclaim 13 further comprising: a guard that is slideably coupled to thehousing, wherein the guard includes a sidewall configured to preventradial motion of the retainer in the initial position and an aperture inthe sidewall configured to allow radial motion of the retainer in aretracted position.
 21. The injection device of claim 13, wherein theram is rotatably fixed and axially moveable relative to the dose settingmechanism.
 22. The injection device of claim 21, wherein the dosesetting mechanism includes a shaft extending partially into and radiallykeyed with an inner shaft of the ram in the initial position and a firedposition.
 23. The injection device of claim 13, wherein the latch isaxially fixed and rotatably moveable relative to the ram.
 24. Theinjection device of claim 1, wherein the firing mechanism includes aspring and the position of the spring being independent from theposition of the dose setting mechanism.
 25. The injection device ofclaim 1, wherein the dose setting mechanism includes a knob rotatablycoupled to the housing.
 26. The injection device of claim 1 furthercomprising a guard slideably coupled to the housing and configured toextend axially past the injection conduit and lock relative to thehousing after removing the injection conduit from the patient.
 27. Theinjection device of claim 1, wherein the injection conduit comprises aneedle.
 28. The injection device of claim 27 further comprising asyringe containing the fluid reservoir, wherein the needle is fixed tothe syringe.
 29. The injection device of claim 1, wherein the injectiondevice is configured to prevent resetting after the firing mechanism isactuated so as to prevent a subsequent injection of the medicament bythe injection device, thereby configuring the injection device as asingle-use injector.
 30. The injection device of claim 1 furthercomprising a safety cap coupled to a distal end of the housing, thesafety cap being coupled to the firing mechanism such that decouplingthe safety cap from the housing allows the firing mechanism to advance apredetermined distance relative to the fluid reservoir to prime thefluid reservoir.
 31. The injection device of claim 1, wherein actuatingthe dose setting mechanism advances the firing mechanism a predetermineddistance relative to the fluid reservoir to prime the fluid reservoir.32. The injection device of claim 1, wherein the firing mechanism isconfigured to deliver each of the selected fraction of the one of theplurality of volumes of medicament over a generally equal amount of timeas compared to one another.
 33. The injection device of claim 1, whereinthe fraction is only greater than or equal to 0.5.
 34. The injectiondevice of claim 1, wherein the selected fraction results in a residualvolume remaining in the fluid reservoir after delivery of 0.18 ml orless.
 35. An injection device for injecting medicament in a patientcomprising: a firing mechanism having an actuator and configured to beselectively preset during assembly to one of a plurality of positionsbased on a maximum volume of medicament to be delivered to the patient;and a dose setting mechanism configured to be selectably adjusted uponuse, independent of the preset of the firing mechanism, to select afraction of the maximum volume of medicament to be delivered to thepatient.
 36. An injection device for injecting medicament in a patientcomprising: a housing configured to house a fluid container having apiston and a fluid reservoir having one of a plurality of volumes ofmedicament, the fluid container including an injection conduit fluidlycoupled to the fluid reservoir configured to define a fluid pathway fromthe fluid reservoir to the patient; a ram coupled to the piston andconfigured to expel the medicament from the fluid reservoir through theinjection conduit; a spring biasing the ram toward the fluid containerin an initial position; a nut threadably coupled to the ram, the nuthaving a plurality of ring shaped grooves or projections; a latch fixedrelative to the housing and engaging a predetermined one of theplurality of ring shaped grooves or projections to retain the ram in oneof a plurality of axial positions against a force of the spring in theinitial position, the nut being rotatable relative to the latch in theinitial position; and a dose setting knob rotatably coupled to thehousing and rotatably fixed and axially moveable relative to the ram inthe initial position.
 37. An injection device for injecting medicamentin a patient comprising: a housing configured to house a fluid containerhaving a piston and a fluid reservoir having one of a plurality ofvolumes of medicament, the fluid container including an injectionconduit fluidly coupled to the fluid reservoir configured to define afluid pathway from the fluid reservoir to the patient; a ram coupled tothe piston and configured to expel the medicament from the fluidreservoir through the injection conduit, the ram having a radiallyextending wing; a latch axially fixed and rotatably moveable relative tothe ram, the ram having a plurality of radial features; a spring biasingthe latch toward the fluid container in an initial position; a retainerfixed relative to the housing and engaging a predetermined one of theplurality of radial features to retain the ram in one of a plurality ofaxial positions against a force of the spring in the initial position; astop having a plurality of axially extending and radially projectingslots each extending a different axial depth, the ram being rotatable toalign the wing with one of the plurality of slots in the initialposition and the wing configured to engage the one of the plurality ofslots in a fired position; and a dose setting knob rotatably coupled tothe housing, the ram being rotatably fixed and axially moveable relativeto the dose setting knob.
 38. A method for assembling an injectiondevice comprising: inserting a fluid container having a fluid reservoirincluding one of a plurality of volumes of medicament into a housing,the fluid container including an injection conduit fluidly coupled tothe fluid reservoir configured to define a fluid pathway from the fluidreservoir to the patient; setting a volume setting mechanism based on asize of the one of the plurality of volumes of medicament; coupling thevolume setting mechanism to a firing mechanism; and coupling the firingmechanism to the fluid reservoir, the firing mechanism configured toexpel the medicament from the fluid reservoir through the injectionconduit, the firing mechanism being coupled to a dose setting mechanismconfigured to select all or a fraction of the one of the plurality ofvolumes of medicament that is injected from the injection conduit whenthe firing mechanism is actuated.
 39. An injection device for injectingmedicament in a patient comprising: a housing configured to house afluid reservoir; an injection conduit fluidly coupled to the fluidreservoir configured to define a fluid pathway from the fluid reservoirto the patient; a firing mechanism coupled to the fluid reservoir andconfigured to expel the medicament from the fluid reservoir through theinjection conduit; and a safety cap coupled to a distal end of thehousing, the safety cap being coupled to the firing mechanism such thatdecoupling the safety cap from the housing allows the firing mechanismto advance a predetermined distance relative to the fluid reservoir toprime the fluid reservoir.